Howard's answered the question well already, and Nicol made some good points about the benefits of having a single standard shared pointer type, rather than lots of incompatible ones.
While I completely agree with the committee's decision, I do think there is some benefit to using an unsynchronized
shared_ptr-like type in special cases, so I've investigated the topic a few times.
If I'm not using multiple threads, or if I am using multiple threads but am not sharing pointer ownership across threads, an atomic smart pointer is overkill.
With GCC when your program doesn't use multiple threads shared_ptr doesn't use atomic ops for the refcount. This is done by updating the reference counts via wrapper functions that detect whether the program is multithreaded (on GNU/Linux this is done simply by detecting whether the program links to
libpthread.so) and dispatch to atomic or non-atomic operations accordingly.
I realised many years ago that because GCC's
shared_ptr<T> is implemented in terms of a
__shared_ptr<T, _LockPolicy> base class, it's possible to use the base class with the single-threaded locking policy even in multithreaded code, by explicitly using
__shared_ptr<T, __gnu_cxx::_S_single>. Unfortunately because that wasn't an intended use case it didn't quite work optimally before GCC 4.9, and some operations still used the wrapper functions and so dispatched to atomic operations even though you've explicitly requested the
_S_single policy. See point (2) at http://gcc.gnu.org/ml/libstdc++/2007-10/msg00180.html for more details and a patch to GCC to allow the non-atomic implementation to be used even in multithreaded apps. I sat on that patch for years but I finally committed it for GCC 4.9, which allows you to use an alias template like this to define a shared pointer type that is not thread-safe, but is slightly faster:
using shared_ptr_unsynchronized = std::__shared_ptr<T, __gnu_cxx::_S_single>;
This type would not be interoperable with
std::shared_ptr<T> and would only be safe to use when it is guaranteed that the
shared_ptr_unsynchronized objects would never be shared between threads without additional user-provided synchronization.
This is of course completely non-portable, but sometimes that's OK. With the right preprocessor hacks your code would still work fine with other implementations if
shared_ptr_unsynchronized<T> is an alias for
shared_ptr<T>, it would just be a little faster with GCC.
If you're using a GCC before 4.9 you could use that by adding the
_Sp_counted_base<_S_single> explicit specializations to your own code (and ensuring noone ever instantiates
__shared_ptr<T, _S_single> without including the specializations, to avoid ODR violations.) Adding such specializations of
std types is technically undefined, but would work in practice, because in this case there's no difference between me adding the specializations to GCC or you adding them to your own code.